JP2005271887A - Electric parking brake device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electric parking brake device braking a vehicle without making the vehicle unstable even when ignition is turned OFF. <P>SOLUTION: The electric parking brake device 1 is provided with: a wheel speed sensor 57 for detecting a speed of the vehicle; an ignition sensor 33 for detecting the state of ignition; an actuator 13 for operating a parking brake 19 by pressing a friction material to a contact material by predetermined brake force F; and ECU 11 for operating the parking brake 19 on the actuator 13 when the ignition sensor detects Off of the ignition and adjusting the brake force F based on the speed detected by the wheel speed sensor 57 before the ignition sensor 33 detects OFF of the ignition. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electric parking brake device.

  2. Description of the Related Art Conventionally, there is known an electric parking brake device that electrically operates and releases a parking brake instead of manual operation by an occupant (see, for example, Patent Document 1). Here, the parking brake includes a contact material (for example, when the parking brake is a drum brake, a cylinder that rotates with a wheel) and a friction material.

The electric parking brake device also includes a parking switch capable of operating the parking brake, and a vehicle speed sensor that detects the speed of the vehicle (hereinafter referred to as “vehicle speed”). When the driver performs an operation operation with the parking switch, the electric parking brake device reads a signal output from the vehicle sensor and calculates a braking force based on the read signal. Thereby, the electric parking brake device can calculate the braking force according to the vehicle speed. Then, the electric parking brake device operates the parking brake by pressing the friction material against the contact material with the calculated braking force. Therefore, since the electric parking brake device can operate the parking brake with a braking force according to the vehicle speed, the vehicle can be braked without making the vehicle unstable. For example, the electric parking brake device can brake the vehicle without shaking the vehicle more than necessary or moving the vehicle more than necessary.
JP 2001-187564 A

  However, if the ignition of the vehicle is turned off for some reason, the signal output from the vehicle speed sensor is interrupted, so the electric parking brake device cannot accurately calculate the braking force according to the vehicle speed. Therefore, in the conventional electric parking brake device, if the driver performs an operation operation with the parking switch when the ignition of the vehicle is turned off, the vehicle may become unstable when the vehicle is braked. there were.

  The present invention has been made in order to solve such a conventional problem. The object of the present invention is to provide a vehicle without destabilizing the vehicle even when the ignition is turned off. An object of the present invention is to provide an electric parking brake device that can be braked.

  The present invention relates to an electric parking brake device that automatically activates a parking brake of a vehicle, wherein the parking brake includes a vehicle speed sensor that detects the speed of the vehicle, an ignition sensor that detects an ignition state of the vehicle, and a friction material included in the parking brake. The operation means for operating the parking brake by pressing the contact member with a predetermined brake force, and when the ignition sensor detects that the ignition is off, the operation means operates the parking brake, and the ignition sensor And a control means for adjusting the braking force based on the speed detected by the vehicle speed sensor before detecting the turning off of the vehicle.

  The electric parking brake device according to the present invention is based on the speed detected by the vehicle speed sensor before the parking brake is activated and the ignition sensor detects the ignition off when the ignition sensor detects the ignition off. Adjust the braking force. Therefore, since the electric parking brake device can perform braking according to the vehicle speed even when the ignition is turned off, the vehicle can be braked without making the vehicle unstable.

(First embodiment)
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings. 1 and 2 are configuration diagrams of the electric parking brake device 1 as a whole, FIG. 1 shows a vehicle installation state of the electric parking brake device 1, and FIG. 2 shows a detailed configuration of the electric parking brake device 1.

  As shown in FIGS. 1 and 2, the electric parking brake device 1 includes an ECU (control means) 11, an actuator (actuation means) 13, an equalizer 15, a PKB cable 17, and a parking brake 19. In addition, the electric parking brake device 1 includes a power supply unit 21, a fuse 23, an emergency release operation unit 25, and a release cable 27. The electric parking brake device 1 further includes an indicator lamp 29, various sensors and switches 31 to 59, a main harness 61, a connector 63, and a body harness 65.

  In the electric parking brake device 1, the actuator 13 controlled by the ECU 11 automatically releases and automatically operates the parking brake 19 installed on the vehicle rear wheel side via the equalizer 15 and the PKB cable 17.

  Here, the parking brake 19 includes a contact material and a friction material, and the contact material is fixed to the wheel. The friction material is connected to the PKB cable 17. The actuator 13 pulls the PKB cable 17 to the actuator 13 side with a predetermined braking force F, thereby pressing the friction material against the contact material with the braking force F. As a result, the actuator 13 operates the parking brake 19. The specific configuration of the actuator 13 will be described later.

  The ECU 11 and the actuator 13 of the electric parking brake device 1 are connected to the power supply unit 21. The power supply unit 21 supplies a voltage to the control unit 10 including the ECU 11 and the actuator 13 via the fuse 23. Specifically, the voltage is supplied to the ECU 11 from the first terminal 21a of the power supply unit 21 via the first fuse 23a. The voltage is supplied to the actuator 13 from the second terminal 21b through the second fuse 23b.

  The emergency release operation unit 25 is connected to the actuator 13 via a release cable 27, and is operated manually to activate the actuator 13 at an early stage and release the parking brake 19.

  The indicator lamp 29 and various sensors / switches 31 to 59 are connected to the ECU 11 via a main harness 61, a connector 63 and a body harness 65.

  Here, the indicator lamp 29 is for displaying a state such as automatic release and automatic operation of the parking brake 19 and a system abnormality, and is turned on and off by a control signal from the ECU 11.

  Each of the various sensor switches 31 to 59 is configured to transmit a signal corresponding to a detection result or input content to the ECU 11. FIG. 3 is a partial configuration diagram of the electric parking brake device 1 according to the first embodiment.

  As shown in the figure, a parking switch (parking operation switch, parking release switch) 31 which is one of various sensors / switches 31 to 59 can operate and release a parking brake. Moreover, the parking switch 31 transmits the operation signal according to operation content to ECU11, when an operation operation or cancellation | release operation is performed. The ECU 11 operates the actuator 13 in accordance with the contents of the operation signal to release and operate the parking brake 19 by electric drive.

  The ignition sensor 33 detects the ignition state, detects whether the ignition is OFF, the accessory is ON, or the ignition is ON, and an ignition signal relating to the detection result is detected. Is transmitted to the ECU 11. Further, the ignition sensor 33 is configured to detect whether or not a vehicle key is inserted, and transmits the detected result to the ECU 11 by including the detected result in an ignition signal.

  An accelerator position sensor (accelerator operation detection sensor) 35 is installed in the accelerator pedal section and detects the operation of the accelerator pedal. Specifically, the accelerator position sensor 35 detects an accelerator pedal depression operation (accelerator pedal ON) and an accelerator pedal return operation (accelerator pedal OFF). Then, the accelerator position sensor 35 transmits an accelerator position signal related to the detected result to the ECU 11.

  A brake pedal switch (brake operation detection sensor) 37 is installed in the brake pedal portion and detects the operation of the brake pedal. Specifically, the brake pedal switch 37 detects a brake pedal depression operation (brake pedal ON) and a brake pedal return operation (brake pedal OFF). Then, the brake pedal switch 37 transmits a brake pedal signal related to the detected result to the ECU 11.

  The clutch position sensor 39 detects the operation of the clutch pedal, and transmits a clutch position signal related to the detected result to the ECU 11.

  The engine speed detection sensor (engine state detection sensor) 41 detects the engine state (specifically, whether the engine is operating or stopped) and the engine speed, and the engine speed related to the detected result. A signal is transmitted to the ECU 11. The engine torque detection sensor 43 detects engine torque and transmits an engine torque signal related to the detected result to the ECU 11.

  The shift position detection sensor 45 detects the state of the shift position, that is, whether it is a drive position or a neutral position, and transmits a shift position signal related to the detected result to the ECU 11.

  The seat pressure sensor 47 is installed on the seat surface of the driver's seat and detects the pressure applied to the driver's seat. Then, the seat pressure sensor 47 transmits a pressure signal related to the detected result to the ECU 11.

  The lining temperature sensor 51 is installed on the friction material provided in the parking brake 19 and detects the temperature Tl of the friction material. Then, the lining temperature sensor 51 transmits a temperature signal related to the detected result to the ECU 11.

  The load sensor 53 is installed inside the actuator 13, measures the load applied to the actuator-side end of the PKB cable 17, and transmits a load signal related to the measured result to the ECU 11.

  The gradient sensor 55 detects the inclination angle of the road surface on which the vehicle is stopped, and transmits an inclination angle signal related to the detected result to the ECU 11.

  A wheel speed sensor (vehicle speed sensor) 57 is provided in a four-wheel axle housing part and detects the vehicle speed. Specifically, the wheel speed sensor 57 detects the speed of each wheel and transmits a wheel speed signal related to the detected result to the ECU 11.

  The reduction gear rotation sensor 59 is installed inside the actuator 13, detects the rotation speed of a gear (a reduction gear 67 described later) in the actuator, and transmits a reduction gear rotation speed signal related to the detected result to the ECU 11.

  The ECU 11 includes a timer (not shown). In addition, the ECU 11 displays a time brake force correlation graph representing the correlation between the time t from the time when the parking brake 19 starts to the current time and the brake force F necessary for stopping the vehicle, and the parking brake 19 operates. Is stored for each vehicle speed at the time of starting.

  The ECU 11 always reads the wheel speed signal output from the wheel speed sensor 57, and reads the ignition signal output from the ignition sensor 33 to determine whether the ignition is off. If the ECU 11 determines that the ignition is off, the average vehicle speed based on the wheel speed signal read immediately before the determination is made, that is, immediately before the ignition sensor 33 detects the ignition off. Vs is calculated. Then, the ECU 11 outputs an operation start signal to the actuator 13 and outputs a control signal to the indicator lamp 29 to light the lamp. Then, the ECU 11 specifies a time brake force correlation graph corresponding to the calculated average vehicle speed Vs. Then, the ECU 11 measures the time t from the time when the operation start signal is output, that is, the time when the parking brake 19 starts to the current time, and the measured time t and the specified time brake force correlation. Based on the graph, the braking force F required to stop the wheel at the current time is determined. Then, the ECU 11 generates an operation signal related to the determined brake force F, and outputs an operation signal related to the determined brake force F to the actuator 13.

  An example of the time brake force correlation graph is shown in FIG. The time brake force correlation graphs 100 to 102 shown in FIG. 5 are drawn on a plane with the time t as the horizontal axis and the brake force F as the vertical axis. The time brake force correlation graph 100 corresponds to a vehicle speed of less than 30 (km / h), and the time brake force correlation graph 101 corresponds to a vehicle speed of 30 (km / h) to less than 80 (km / h). The time brake force correlation graph 102 corresponds to a vehicle speed of 80 (km / h) or more. As shown in the time brake force correlation graphs 100 to 102, the ECU 11 gradually increases the brake force F as the vehicle speed increases. For example, when the vehicle speed is 80 (km / h), if the actuator 13 presses the friction material against the contact material with the brake force F corresponding to the time brake force correlation graph 100, the vehicle shakes more than necessary. This is because the vehicle becomes unstable when the vehicle is braked.

  Further, the ECU 11 outputs a release signal to the actuator 13 when releasing the parking brake 19 (for example, when a release operation is performed by the parking switch 31). The actuator 13 automatically releases and automatically operates the parking brake 19 based on the operation signal and the release signal.

  As shown in FIG. 3, the actuator 13 includes a motor M and a speed reducer 67. Here, the control unit 10 including the actuator 13 will be described with reference to FIG.

  FIG. 4 is an internal configuration diagram of the control unit 10 of the electric parking brake device 1. As shown in the figure, the control unit 10 has a configuration in which an ECU 11 and an actuator 13 are housed in a housing 69. Specifically, the ECU 11 is connected to the motor M. The motor M is connected to a speed reducer 67. The speed reducer 67 includes a drive gear 71, a guide shaft 73, a first driven gear 75, a drive shaft 77, and a second driven gear 79.

  When the motor M is given an operation start signal from the ECU 11, the motor M starts driving in the direction of pulling the PKB cable 17 to the actuator 13 side among the forward rotation driving and the reverse rotation driving. Thereafter, the motor M adjusts the rotational force of the motor M based on the operation signal given from the ECU 11 so that the force pulling the PKB cable 17, that is, the brake force F matches the brake force F determined by the ECU 11. . Further, the motor M drives the PKB cable 17 in the direction of feeding out to the parking brake 19 side in the forward rotation drive or the reverse drive based on the release signal given from the ECU 11.

  The drive gear 71 is connected to the motor M and transmits the rotational force from the motor M to the first driven gear 75 that is pivotally supported by the guide shaft 73. The first driven gear 75 is connected to a second driven gear 79 that is pivotally supported by the drive shaft 77, and transmits its rotational force to the second driven gear 79. Further, the drive shaft 77 is threaded and a drive nut 81 is attached so as to mesh with the threaded portion. For this reason, the drive nut 81 moves along the extending direction of the drive shaft 77 when the second driven gear 79 rotates. The drive nut 81 is connected to a casing 83 having a load sensor 53 (not shown). Therefore, the casing 83 can move in the longitudinal direction of the drive shaft 77 in accordance with the movement of the drive nut 81.

  With this configuration, when the ECU 11 drives the motor M to rotate forward or reversely, the drive shaft 77 is rotated by the rotation of the second driven gear 79, and the casing 83 is moved along with the movement of the drive nut 81. The PKB cable 17 is drawn to the actuator 13 side or extended to the parking brake 19 side. That is, the actuator 13 pulls in or pulls out the PKB cable 17. And by this drawing, the PKB cable 17 presses the friction material of the parking brake 19 against the contact material. Thereby, the parking brake 19 operates. Further, by this feeding, the PKB cable 17 separates the friction material of the parking brake 19 from the contact agent. As a result, the parking brake 19 is released.

  Since the motor M adjusts the rotational force of the motor M as described above when the parking brake 19 is operated, the actuator 13 pulls in the PKB cable 17 with the brake force F determined by the ECU 11. As a result, the friction material of the parking brake 19 is pressed against the contact material with the brake force F determined by the ECU 11, so the actuator 13 presses the friction material against the contact material with the brake force F determined by the ECU 11. . In other words, the ECU 11 adjusts the braking force of the actuator 13.

  Next, the detailed operation of the electric parking brake device 1 will be described with reference to the flowchart shown in FIG.

  In step ST <b> 11 shown in FIG. 6, the ECU 11 always reads the wheel speed signal output from the wheel speed sensor 57. Next, the ECU 11 reads the ignition signal output from the ignition sensor 33 and determines whether or not the ignition is off.

  As a result, when the ECU 11 determines that the ignition is off (step ST11: YES), the ECU 11 proceeds to step ST12, and when it determines that the ignition is on (step ST11: NO). This process is terminated.

  In step ST12, the ECU 11 calculates the average vehicle speed Vs based on the wheel speed signal read by the ECU 11 immediately before the ignition sensor 33 detects the ignition off.

  Specifically, the ECU 11 calculates the average vehicle speed Vs using the following equation (1). Here, Vfr is the speed of the right front wheel, and Vfl is the speed of the left front wheel. Vrr is the speed of the right rear wheel, and Vrl is the speed of the left rear wheel.

Vs = (Vfr + Vfl + Vrr + Vrl) / 4 (1)
In step ST13, the ECU 11 outputs an operation start signal to the actuator 13 and outputs a control signal to the indicator lamp 29 to light the lamp.

  Next, when the operation start signal is given from the ECU 11, the motor M starts driving in the direction of pulling the PKB cable 17 toward the actuator 13 among the forward rotation driving and the reverse rotation driving. As a result, the actuator 13 starts to pull in the PKB cable 17, and the parking brake 19 starts to operate.

  Next, the ECU 11 specifies a time brake force correlation graph corresponding to the average vehicle speed Vs calculated in step ST12. Next, the ECU 11 measures a time t from when the parking brake 19 starts to the current time, and based on the measured time t and the specified time brake force correlation graph, The braking force F required for stopping the wheel is determined. Next, the ECU 11 generates an operation signal related to the determined brake force F, and outputs an operation signal related to the determined brake force F to the actuator 13. Next, the motor M adjusts the rotational force of the motor M based on the operation signal given from the ECU 11 so that the force pulling the PKB cable 17, that is, the brake force F matches the brake force F determined by the ECU 11. . As a result, the actuator 13 retracts the PKB cable 17 with the braking force F determined by the ECU 11.

  In step ST14, the indicator lamp 29 is turned on based on a control signal given from the ECU 11. Accordingly, the indicator lamp 29 notifies the vehicle occupant that the parking brake 19 is operating. Thereafter, the ECU 11 ends this process.

  As described above, according to the first embodiment, the electric parking brake device 1 activates the parking brake 19 when the ignition sensor 33 detects that the ignition is turned off, and the ignition sensor 33 turns off the ignition. The brake force F is adjusted based on the speed detected by the wheel speed sensor 57 before detecting. Therefore, the electric parking brake device 1 can perform braking according to the vehicle speed even when the ignition is turned off, so that the vehicle can be braked without making the vehicle unstable.

  Moreover, since the electric parking brake device 1 stores the time brake force correlation graph and determines the brake force F based on the time brake force correlation graph, the brake is performed more quickly than when the brake force F is determined by calculation. The force F can be determined. Therefore, the electric parking brake device 1 can brake the vehicle more quickly than when the braking force F is determined by calculation.

  The electric parking brake device 1 averages the speeds Vfr, Vfl, Vrr, and Vrl of each wheel to calculate the average vehicle speed Vs and determines the braking force F based on the average vehicle speed Vs. Compared with the case where the braking force F is determined, the braking force F can be determined based on a value closer to the actual vehicle speed. Therefore, the electric parking brake device 1 can perform braking according to the vehicle speed more accurately than in the case where the braking force F is determined based on the speed of each wheel.

(Second Embodiment)
Next, the electric parking brake device 2 according to the second embodiment will be described. The electric parking brake device 2 according to the second embodiment is substantially the same as the electric parking brake device 1, but is different in terms of automatic operation processing of the parking brake 19. Hereinafter, the detailed operation of the electric parking brake device 2 will be described with reference to the flowchart shown in FIG.

  In step ST21 shown in FIG. 7, the ECU 11 always reads the wheel speed signal output from the wheel speed sensor 57. Next, the ECU 11 reads the ignition signal output from the ignition sensor 33 and determines whether or not the ignition is off.

  As a result, when the ECU 11 determines that the ignition is off (step ST21: YES), the ECU 11 proceeds to step ST22, and when it is determined that the ignition is on (step ST21: NO). This process is terminated.

  In step ST22, the ECU 11 reads the signals output from the brake pedal switch 37 and the parking switch 31, and detects whether the brake pedal switch 37 has depressed the brake pedal, or the parking switch 31 operates. Determine whether or not.

  As a result, when the ECU 11 detects that the brake pedal switch 37 has depressed the brake pedal or the parking switch 31 has operated (step ST22: YES), the ECU 11 proceeds to step ST23. In other cases (step ST23: NO), this process ends.

  In step ST23 to step ST25, the electric parking brake device 2 performs the same processing as step ST12 to step ST14 shown in FIG.

  As described above, in the second embodiment, when the ignition sensor 33 detects that the ignition has been turned off, the electric parking brake device 2 can detect the parking brake only when the operating condition based on the driver's intention is satisfied. 19 is activated. As a result, the electric parking brake device 2 operates the parking brake 19 in accordance with the driver's intention after the ignition sensor 33 detects the ignition off. Therefore, the driver can operate the parking brake 19 in accordance with his / her own intention after the ignition sensor 33 detects that the ignition is turned off. Therefore, the electric parking brake device 2 can operate the vehicle at the time of vehicle braking. Can be improved as compared with the first embodiment.

  The electric parking brake device 2 activates the parking brake 19 when the driver operates the parking brake 19 with the parking switch 31 after the ignition sensor 33 detects that the ignition is turned off. Here, it can be said that the driver intends to operate the parking brake 19 when the driver operates the parking brake 19. Therefore, the electric parking brake device 2 can operate the parking brake 19 in accordance with the driver's intention.

  The electric parking brake device 2 operates the parking brake 19 when the driver depresses the brake pedal after the ignition sensor 33 detects that the ignition is turned off. Here, it can be said that the driver intends to stop the vehicle at least when the driver depresses the brake pedal. In other words, it can be said that the driver intends to operate the parking brake 19. Therefore, the electric parking brake device 2 can operate the parking brake 19 in accordance with the driver's intention.

(Third embodiment)
Next, the electric parking brake device 3 according to the third embodiment will be described. The electric parking brake device 3 according to the third embodiment is substantially the same as the electric parking brake device 1, but is different in the automatic release processing of the parking brake 19. The detailed operation of the electric parking brake device 3 will be described below with reference to the flowchart shown in FIG.

  In steps ST31 to ST34 shown in FIG. 8, the electric parking brake device 3 performs the same processing as steps ST11 to ST14 shown in FIG.

  In step ST35, the ECU 11 reads the signals output from the accelerator position sensor 35 and the parking switch 31, and detects whether the accelerator position sensor 35 has depressed the accelerator pedal or the parking switch 31 performs a releasing operation. Determine whether or not.

  As a result, if the ECU 11 determines that the accelerator position sensor 35 detects the depression of the accelerator pedal or that the release operation has been performed by the parking switch 31 (step ST35: YES), the ECU 11 proceeds to step ST36. In other cases (step ST35: NO), this process ends.

  In step ST36, the ECU 11 outputs a release signal to the actuator 13 and outputs a control signal to the indicator lamp 29 to turn off the lamp. Next, the motor M drives the PKB cable 17 in the direction of feeding out to the parking brake 19 side in the forward rotation drive or the reverse rotation drive based on the release signal given from the ECU 11. As a result, the actuator 13 releases the parking brake 19. The indicator lamp 29 is turned off based on a control signal given from the ECU 11. Thereby, the indicator lamp 29 can notify the vehicle occupant that the parking brake 19 has been released. Thereafter, the electric parking brake device 3 ends this process.

  As described above, in the third embodiment, the electric parking brake device 3 releases the parking brake 19 only when the release condition based on the driver's intention is satisfied after the parking brake 19 is operated. As a result, the electric parking brake device 3 can release the parking brake 19 in accordance with the driver's intention after the parking brake 19 is operated. The operability can be improved as compared with the first and second embodiments.

  The electric parking brake device 3 releases the parking brake 19 when the driver depresses the accelerator pedal after the parking brake 19 is operated. Here, it can be said that the driver intends to release the parking brake 19 when the driver depresses the accelerator pedal. Therefore, the electric parking brake device 3 can release the parking brake 19 in accordance with the driver's intention.

  The electric parking brake device 3 releases the parking brake 19 when the driver performs the releasing operation of the parking brake 19 with the parking switch 31 after the parking brake 19 is operated. Here, it can be said that the driver intends to release the parking brake 19 when the driver performs the releasing operation of the parking brake 19. Therefore, the electric parking brake device 3 can release the parking brake 19 in accordance with the driver's intention.

(Fourth embodiment)
Next, the electric parking brake device 4 according to the fourth embodiment will be described. The electric parking brake device 4 according to the fourth embodiment is substantially the same as the electric parking brake device 2, but is different in terms of automatic release processing of the parking brake 19. The detailed operation of the electric parking brake device 4 will be described below with reference to the flowchart shown in FIG.

  In steps ST41 to ST45 shown in FIG. 9, the electric parking brake device 4 performs the same processing as steps ST21 to ST25 shown in FIG.

  In step ST46, the ECU 11 reads the signals output from the accelerator position sensor 35 and the parking switch 31, and detects whether the accelerator position sensor 35 has depressed the accelerator pedal or the parking switch 31 performs a releasing operation. Determine whether or not.

  As a result, if the ECU 11 determines that the accelerator position sensor 35 detects the depression of the accelerator pedal or that the release operation has been performed by the parking switch 31 (step ST46: YES), the ECU 11 proceeds to step ST47. In other cases (step ST46: NO), this process ends.

  In step ST <b> 47, the ECU 11 outputs a release signal to the actuator 13, and outputs a control signal for turning off the lamp to the indicator lamp 29. Next, the motor M drives the PKB cable 17 in the direction of feeding out to the parking brake 19 side in the forward rotation drive or the reverse rotation drive based on the release signal given from the ECU 11. As a result, the actuator 13 releases the parking brake 19. The indicator lamp 29 is turned off based on a control signal given from the ECU 11. Thereafter, the electric parking brake device 4 ends this process.

  As described above, in the fourth embodiment, the electric parking brake device 4 performs the same processing as that of the third embodiment after the parking brake 19 is operated. An effect can be obtained.

(Fifth embodiment)
Next, an electric parking brake device 5 according to a fifth embodiment will be described. The electric parking brake device 5 according to the fifth embodiment is substantially the same as the electric parking brake device 1, but is different in the automatic release processing of the parking brake 19. The detailed operation of the electric parking brake device 5 will be described below with reference to the flowchart shown in FIG.

  In steps ST51 to ST54 shown in FIG. 10, the electric parking brake device 5 performs the same processing as in steps ST11 to ST14 shown in FIG.

  In step ST55, the ECU 11 reads the signals output from the ignition sensor 33 and the engine speed detection sensor 41, the ignition sensor 33 detects the ignition being turned on, and the engine speed detection sensor 41 operates the engine. Determine whether it was detected.

  As a result, when the ECU 11 determines that the ignition sensor 33 detects that the ignition is on and the engine speed detection sensor 41 detects the operation of the engine (step ST55: YES), the ECU 11 proceeds to step ST56. Otherwise (step ST55: NO), this process ends.

  In step ST <b> 56, the ECU 11 outputs a release signal to the actuator 13, and outputs a control signal for turning off the lamp to the indicator lamp 29. Next, the motor M drives the PKB cable 17 in the direction of feeding out to the parking brake 19 side in the forward rotation drive or the reverse rotation drive based on the release signal given from the ECU 11. As a result, the actuator 13 releases the parking brake 19. The indicator lamp 29 is turned off based on a control signal given from the ECU 11. Thereafter, the electric parking brake device 5 ends this process.

  As described above, in the fifth embodiment, the electric parking brake device 5 releases the parking brake 19 only when the release condition based on the driver's intention is satisfied after the parking brake 19 is operated. Thus, the electric parking brake device 5 can release the parking brake 19 according to the driver's intention after the parking brake 19 is operated. The operability can be improved as compared with the first and second embodiments.

  The electric parking brake device 5 operates the parking brake 19 when the ignition is turned on and the engine is operated after the parking brake 19 is operated. Here, it can be said that the driver intends to release the parking brake 19 when the ignition is turned on and the engine is operated. Therefore, the electric parking brake device 5 can release the parking brake 19 in accordance with the driver's intention.

(Sixth embodiment)
Next, the electric parking brake device 6 according to the sixth embodiment will be described. The electric parking brake device 6 according to the sixth embodiment is substantially the same as the electric parking brake device 2, but is different in terms of automatic release processing of the parking brake 19. Hereinafter, the detailed operation of the electric parking brake device 6 will be described with reference to the flowchart shown in FIG.

  In steps ST61 to ST65 shown in FIG. 11, the electric parking brake device 6 performs the same processing as in steps ST21 to ST25 shown in FIG.

  In step ST66, the ECU 11 reads the signals output from the ignition sensor 33 and the engine speed detection sensor 41, the ignition sensor 33 detects the ignition being turned on, and the engine speed detection sensor 41 operates the engine. Determine whether it was detected.

  As a result, when the ECU 11 determines that the ignition sensor 33 detects that the ignition is turned on and the engine speed detection sensor 41 detects the operation of the engine (step ST66: YES), the ECU 11 proceeds to step ST67. Otherwise (step ST66: NO), this process ends.

  In step ST <b> 67, the ECU 11 outputs a release signal to the actuator 13, and outputs a control signal for turning off the lamp to the indicator lamp 29. Next, the motor M drives the PKB cable 17 in the direction of feeding out to the parking brake 19 side in the forward rotation drive or the reverse rotation drive based on the release signal given from the ECU 11. As a result, the actuator 13 releases the parking brake 19. The indicator lamp 29 is turned off based on a control signal given from the ECU 11. Thereafter, the electric parking brake device 6 ends this process.

  As described above, in the sixth embodiment, the electric parking brake device 6 performs the same processing as that of the fifth embodiment after the parking brake 19 is operated, so that the same processing as that of the fifth embodiment is performed. An effect can be obtained.

  As mentioned above, although this invention was demonstrated based on embodiment, this invention is not restricted to the said embodiment, Each embodiment may be combined and it adds in the range which does not deviate from the meaning of this invention. Also good.

It is a block diagram of the whole electric parking brake apparatus, and has shown the vehicle installation state of the electric parking brake apparatus. It is a block diagram of the whole electric parking brake apparatus, and has shown the detailed structure of the electric parking brake apparatus. It is a partial block diagram of an electric parking brake device. It is an internal block diagram of a control unit. It is explanatory drawing which shows an example of a time brake force correlation graph. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus. It is a flowchart which shows detailed operation | movement of an electric parking brake apparatus.

Explanation of symbols

1-6 ... Electric parking brake device 11 ... ECU (control means)
13 ... Actuator (actuating means)
19 ... parking brake 29 ... indicator lamp 31 ... parking switch (parking operation switch, parking release switch)
33 ... Ignition sensor 35 ... Accelerator position sensor (Accelerator operation detection sensor)
37 ... Brake pedal switch (brake operation detection sensor)
41. Engine speed detection sensor (engine state detection sensor)
57. Wheel speed sensor (vehicle speed sensor)

Claims (9)

In the electric parking brake device that automatically operates the parking brake of the vehicle,
A vehicle speed sensor for detecting the speed of the vehicle;
An ignition sensor for detecting an ignition state of the vehicle;
An operating means for operating the parking brake by pressing the friction material provided in the parking brake against the contact material provided in the parking brake with a predetermined braking force;
When the ignition sensor detects that the ignition is turned off, based on the speed detected by the vehicle speed sensor before operating the parking brake by the operating means and before the ignition sensor detects the ignition being turned off. And an electric parking brake device comprising: a control means for adjusting the brake force.   When the ignition sensor detects that the ignition is turned off, the control means causes the operation means to operate the parking brake only when an operation condition based on a driver's intention is satisfied. The electric parking brake device according to claim 1. A brake operation detection sensor for detecting an operation of a brake pedal of the vehicle;
3. The electric parking brake device according to claim 2, wherein the operating condition is that the brake operation detection sensor detects a depression operation of the brake pedal. A parking operation switch capable of operating the parking brake;
4. The electric parking brake device according to claim 2, wherein the operating condition is that the parking brake is operated by the parking operation switch. The actuating means releases the parking brake by separating the friction material from the contact material,
5. The control unit according to claim 1, wherein the control unit causes the operation unit to release the parking brake only when a release condition based on a driver's intention is satisfied after the parking brake is operated. The electric parking brake device according to any one of claims. An accelerator operation detection sensor for detecting an operation of an accelerator pedal of the vehicle;
6. The electric parking brake device according to claim 5, wherein the release condition is that the accelerator operation detection sensor detects a depression operation of the accelerator pedal. A parking release switch capable of releasing the parking brake;
The electric parking brake device according to claim 5 or 6, wherein the release condition is that a release operation of the parking brake is performed by the parking release switch. An engine state detection sensor for detecting the state of the engine of the vehicle;
8. The release condition according to claim 5, wherein the ignition sensor detects that the ignition is turned on, and the engine state detection sensor detects the operation of the engine. The electric parking brake device described in 1.   The control means starts the operation of the parking brake based on a time brake force correlation graph showing a correlation between the time from the time when the parking brake starts to the current time and the braking force necessary for stopping the vehicle. Each time the vehicle speed is stored, and the time from when the parking brake starts to the current time is measured, and the stored time brake force correlation graph and the measured The brake force is adjusted based on time and the speed detected by the vehicle speed sensor before the ignition sensor detects that the ignition is turned off. The electric parking brake device described in 1.

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